Methods of extruding plastic netting

ABSTRACT

Methods of extruding tubular plastic netting from extrusion orifices in concentric, counterrotatable inner and outer dies in which the plastic filaments extruded therefrom have substantially the same downward relative velocity so as to form netting intersections with substantially no relative shear movement between intersecting filaments.

This is a division of application Ser. No. 450,859, filed Mar. 13, 1974 now U.S. Pat. No. 3,957,565.

This invention relates to methods of extruding plastic netting or the like.

More particularly, this invention is concerned with methods of extruding a plurality of filaments of plasic in such manner as to form a tube of netting in which the filaments overlap or intersect one another and are joined at intersections or "knots." Such extruding apparatus is shown, for example in U.S. Pat. Nos. 2,919,467, 3,607,084, 3,560,306, 3,620,883 and in East German Pat. No. 52,801. Tubular plastic netting is conventionally produced by forcing plastic melt through a series of extrusion orifices in an inner die and through an adjacent circular series of extrusion orifices in an outer die surrounding the inner die, the inner and outer dies being rotatable relative to one another. Upon cooling, the netting is oftentimes heated and stretched to orient the molecular structure of the plastic so as to enhance strength, size and heat-shrink characteristics for subsequent packaging usage.

Heretofore, conventionally extruded netting oftentimes did not have sufficient strength to withstand subsequent stretching operations. Also, in the extrusion of prior netting, the intersections per se were stretched to such an extent as to result in unsatisfactory netting when used in subsequent packaging operations.

SUMMARY OF THE INVENTION

Among the several objects of the invention may be noted the provision of methods of extruding plastic netting in which the plastic filaments are extruded in such manner that the intersecting filaments have substantially no movement relative to one another when they are joined to form intersections; the provision of such methods which produce plastic netting having uniform mesh size; the provision of such methods which insure that during subsequent orientation of the netting, the individual filaments rather than the intersections of the netting are stretched; and provision of such methods which are economical in use and are reliable in operation.

Briefly, the method of this invention of extruding tubular plastic netting involves extruding a first generally circular series of filaments with each of the filaments inclined at one direction with respect to a plane including the longitudinal axis of the netting and extruding a second generally circular series of filaments concentric with the first series of filaments and each of the second series of filaments inclined in the opposite direction with respect to the above-mentioned plane while rotating the first and second series in opposite directions at an angular velocity such that the resultant tangential velocity of the filaments upon extrusion relative to a stationary point is zero. The filaments of the first and second series are joined at their intersections.

Other objects and features of this invention will be in part apparent and in part pointed out hereinafter.

BACKGROUND OF THE INVENTION BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side elevation of extrusion apparatus employing the method this invention with parts broken away, illustrating a tube of plastic netting as it extends downwardly after having been extruded;

FIG. 2 is an enlargement of a portion of FIG. 1 showing inner and outer dies at the lower end of the extrusion apparatus;

FIG. 3 is a perspective of a lower member of the inner die;

FIG. 4 is a perspective of a lower ring of the outer die;

FIG. 5 is a semidiagrammatic view showing an extrusion orifice in the outer die illustrating the resultant velocity of a plastic filament extruded from an outer die extrusion orifice as the outer die rotates;

FIG. 6 is a semidiagrammatic view of a portion of the inner die similar to FIG. 5 illustrating the resultant velocity of a filament extruded from an inner die orifice as the inner die rotates;

FIG. 7 is an enlarged view showing the intersection of two filaments of the tubular netting;

FIG. 8A - 8C views showing relative rotary positions of the inner and outer die orifices corresponding to formation of netting at lines 8A--8A , 8B--8B and 8C--8C of FIG. 7;

FIG. 9 is a semidiagrammatic representation of netting extruded by prior art extruding apparatus; and

FIG. 10 is a semidiagrammatic representation of netting extruded by apparatus of this invention.

Corresponding reference characters indicate corresponding parts throughout the several views of the drawings.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to the drawings, apparatus for extruding plastic netting N is shown to comprise a generally vertical extrusion housing 1. A shaft 3 extends through housing 1 from the upper end of the housing and is mounted as by means of suitable bearings for rotation in one direction, as incated by the arrow in FIG. 1, on a generally vertical axis within the housing. A barrel 7 is mounted as by means of roller thrust bearings 9 for rotation in the lower end of the housing in the opposite direction, as indicated by the second arrow in FIG. 1, on the vertical axis of the housing and the shaft. The shaft is of smaller diameter than the internal diameter of the extrusion housing so that there is an annular space 11 around the shaft between the shaft and the barrel for the downward flow of plastic heated to extrusion temperature and supplied to the housing via an inlet 13. The shaft has an enlarged-diameter cylindrical lower end head 15 with a frustoconical inwardly tapered lower end 17. The barrel surrounds the lower end head of the shaft with a second annular space 19 therebetween connected to the first annular space 11 for the downward passage of the molten plastic to be extruded. The barrel is formed with an internal frustoconical surface 21 at its lower end surrounding the tapered lower end of head 15 and flaring or tapering outwardly opposite the taper 17.

At the lower end of shaft 3 is an inner extrusion die 23 and at the lower end of barrel 7 is an outer die 25 having a central opening and surrounding the inner die, the dies being counterrotatable in opposite directions relative to one another on a common die axis X--X. The inner die has a circular series of extrusion orifices 27 for extrusion of filaments F_(I) of plastic therethrough and out from the bottom of the inner die, and the outer die has a circular series of extrusion passages 29 for the extrusion of filaments F_(O) of plastic therethrough and out the bottom of the outer die. The extrusion orifices extend through dies 23 and 25 from the insides thereof in communication with annular space 19 to the outside of the dies. As appears in FIGS. 3 and 4, the inner and outer die orifices are inclined at an angle with respect to die axes X--X, as will appear, so that they meet on the surface of an imaginary cylinder 31 (shown in phantom at 31 in FIG. 2) for coalescence of filaments F_(I) and F_(O) extruded via passages 27 and 29.

As shown in FIG. 3, the extrusion orifices or passages of inner die 23 are inclined in one direction with respect to a plane perpendicular to the die axis X--X (i.e., with respect to the top or bottom face of the die), and as shown in FIG. 4, the extrusion orifices 29 of outer die 25 are inclined in the opposite direction with respect to the above-mentioned plane so that one end of each passage leads and the other trails as its respective die rotates. In both inner and outer dies, the leading ends of their orifices are shown to be their inner ends and their trailing ends are shown to be their outer ends.

Means, indicated generally at 33, is provided for splitting the downward flow of plastic into two separate streams, one for the extruding orifices 27 of the inner die and the other for the extrusion orifices 29 of the outer die. As will appear, this splitting means is formed substantially to equalize the rate of flow of the plastic to the extrusion orifices. The inner and outer dies have entrance passages 35 and 37 extending down from the top. The splitting means directs one stream of plastic into the entrance passages 35 of the inner die and the other into the entrance passages 37 of the outer die. As shown in FIG. 2, it splits the flared lowered end of annular space 19 into an inner annular entrance channel 39 opening into the upper ends of the entrance passages 35 of the inner die and an outer annular entrance channel 41 opening into the upper ends of the entrance passages 37 of the outer die.

As best shown in FIG. 2, inner die 23 comprises a circular upper member 43 secured, as by bolts 44, to the lower end of shaft 3 (i.e., it is bolted to the bottom end of tapered head 15) and is of larger diameter than head 15 of the shaft and extends radially outwardly therefrom. This upper member has a peripheral rim 45 projecting upwardly, and a circular lower member 49 secured, as with bolts 51, to the bottom end thereof. Member 49 has on its surface a frustoconical surface 53 (see FIG. 4) flaring outwardly in downward direction. As shown in FIG. 4, extrusion orifices 27 of the inner die are formed by slots in the inner die frustoconical surface 53. For example, these extrusion slots or orifices are shown to be inclined or angled at about 30° to the die axis X--X (see FIG. 2) and are inclined relative to generatrices of conical surface 53 at an angle of about 45°. However, it will be understood that these angles could vary considerably from the above-stated values.

As shown in FIG. 2, the inner die rim 45 has a lower beveled edge 55 sealingly engaging the inner die frustoconical surface 53 and closing inner die slots or orifices 27. An inner die manifold 56 is further constituted by an annular space between the inner die rim 45 and the lower member 49 above the inner die rim beveled edge 55, this annular space being in communication with the upper ends of slots 27. Entrance passages 35 are arranged in member 43 as a circular series of equally spaced holes around its margin adjacent rim 47, these entrance passages providing communication between the inner die manifold 56 and annular space 19.

Outer die 25 comprises a circular upper ring 57 secured to barrel 7 by means of bolts 59. Ring 57 is of larger diameter than inner die 23 and extends below barrel 7 and has an inner peripheral rim 61 extending downwardly and upwardly therefrom. Outer die 25 further includes a lower ring member 63 secured, as by bolts 65, on the bottom face of ring 57. Ring 63 has a generally frustoconical inner periphery 67 flaring outwardly in upward direction. The outer die extrusion orifices 29 are formed by slots in the outer die frustoconical periphery (see FIG. 5). For example, these extrusion slots or orifices are shown to be inclined or angled at about 30° to the die axis X--X and are inclined relative to generatrices of conical surface 67 at an angle of about 45°.

Outer die rim 61 has a lower beveled edge 69 engaging the outer die frustoconical periphery 67 in rotary sealing engagement and this closes the outer die extrusion slots. An outer die manifold 70 is formed by an annular space between outer die rim 61 and lower ring 63 above beveled edge 69 in communication with the upper ends of the slots. Entrance passages 37 are arranged in ring 57 as a circular series of equally spaced holes around its margin adjacent rim 61, these entrance passages providing communication between the outer die manifold 70 and annular space 19.

Rims 45 and 61 are in rotary sealing engagement with one another and their upper ends are beveled, as indicated at 71. A sprocket 72 is affixed to the upper end of shaft 3 for rotating the shaft and the inner die. As shown in FIG. 1, upper ring 57 includes a sprocket 73 around which a chain may be trained for rotating the outer die and barrel 7 in the direction opposite to the rotation of inner die 23.

Housing 1 comprises an upper section 77 having an outwardly extending flange 79 at its lower end with a downwardly extending annular rim 81 on this flange, and a cylindrical lower section 83 secured, as indicated at 85, to the rim and extending downwardly therefrom. Bearings 9 for barrel 7 are mounted in section 83, with a retainer 87 at the lower end of the section. After being extruded, netting N surrounds a mandrel 89 and its cooled in a water bath 91 (see FIG. 1).

FIG. 7 is a diagrammatic representation of two intersecting netting filaments F_(I) and F_(O) extruded by apparatus of this invention and forming an intersection I. FIGS. 8A - 8C are enlarged bottom views of a portion of dies 23 and 25. FIGS. 8A and 8C illustrate out-of-register conditions of the lower ends of extrusion orifices 27 and 29 of the inner and outer dies 23 and 25. A single filament F_(I) is extruded from each of the inner die orifices 27, and a single filament F_(O) is extruded from each of the outer die orifices 29. As shown in FIG. 10, the filaments F_(I) extruded by the inner die form a first series of filaments in which each filament F_(I) is substantially parallel to the other filaments F_(I) in the series, this first series of filaments being inclined at a first helical angle of approximately 45° with respect to the die axis X--X. The outer die 25 extrudes a second series of filaments F_(O) with each of these filaments being equally spaced from one another and parallel to one another and inclined at a second helical angle of about 45° with respect to the die axis X--X, opposite to the direction of the helix angle of the first set of filaments F_(I). As dies 23 and 25 counterrotate, netting N having intersections I between filaments F_(I) and F_(O) is generated, the intersections being formed when the extrusion orifices 27 and 29 are in register at their lower ends.

As shown in FIG. 9, filaments extruded from conventional extrusion inner and outer dies 201 and 203, respectively, each having straight or unbiased orifices 205 and 207 (i.e., orifices parallel to the die axis) exit their respective orifices parallel to the die axis and are immediately bent (approximately 45°) to assume an inclined position corresponding to the desired netting geometry. This bending of the filaments causes shear in the filaments and at their intersections which in turn may substantially weaken the netting. These weakened intersections may separate or delaminate during subsequent heating and stretching operations for orienting the molecular structure of the plastic netting and this delamination may render the netting unsuitable for commercial use.

As shown in FIG. 10, filaments F_(I) and F_(O) of netting N extruded by apparatus of the present invention are inclined with respect to the netting axis X--X at substantially the angle the filaments will occupy in netting N after the filaments have been cooled. Thus, the extrusion orifices 27 and 29 establish the direction of the netting filaments and intersections I are formed at substantially the angle at which the filaments are extruded from the dies. Because of this, the filaments need not move relative to one another or relative to the dies as the netting cools, and thus little or no shear is introduced into the individual filaments or into the intersection this insures that the strength of the intersections prior to the orientation of the netting is maximized.

Also, upon extrusion of filaments from conventional unbiased extrusion orifices, bending of the filaments causes movement thereof which may cause adjacent filaments to overlap with one another where not desired. Because the filaments are at least still partially molten, this overlapping may cause inadvertent bonding of the filaments and may prevent the formation of netting having a uniform mesh size and shape. With the biased extrusion orifices 27 and 29 of the present invention, the filaments F_(I) and F_(O) extruded therefrom need not be bent to conform to the desired netting geometry. Thus, with the apparatus and methods of this invention, the tendency of adjacent filaments to overlap is substantially reduced, which results in improved quality of the netting.

In accordance with this invention, the plastic netting N is extruded with an included angle A (see FIG. 7) between intersecting filaments F_(I) and F_(O) of about 70° - 120° and preferably 90° or greater. An included angle such as above specified is particularly advantageous in subsequent heating and stretching operations for orienting the molecular structure of the netting. By providing such an included angle between intersecting filaments, axial stretching of the netting causes bending of each of the filaments adjacent intersections I, thus insuring that the individual filaments, rather than the intersection I per se, undergo axial elongation during the stretching operation. By substantially preventing stretching of intersections I during the stretching operation, the strength of the bond between the filaments at the intersections is enhanced and the tendency of the filaments to separate or delaminate at the intersections is substantially reduced.

Referring now to FIG. 5, a portion of outer die 25 is depicted as having one extrusion orifice 29 angled therein with respect to a generatrix of surface 67 at an angle of about 45° away from the horizontal plane of the bottom of the dies. Of course, it will be understood that the included angle A between the intersecting filaments F_(I) and F_(O) may be varied by varying the angle of orifices 27 and 29 with respect to the generatrices of their respective conical die surfaces 53 and 67, respectively. The outer die is rotated, as indicated by the arrow in FIG. 5, at a constant angular velocity represented by the generally horizontal tangential velocity vector V_(AO). Plastic filament F_(O) extruded from the trailing end of orifice 29 exits coaxially with the orifice at a velocity relative to the outer die as represented by the velocity vector V_(EO). It will be understood that the direction of vector V_(EO) depends on the angle of inclination of orifice 29 relative to the generatrix of the surface 67 and the conical angle of surface 67, and its magnitude depends on the extruding pressure within the annular space 19, the viscosity of the plastic melt, and other factors. Preferably, the plastic is extruded from orifice 29 in such manner that the horizontal tangential component V_(HO) of vector V_(EO) is substantially equal (but opposite in direction to) the angular horizontal tangential velocity V_(AO) of the outer die so that the resultant downward velocity of the filaments relative to a stationary reference is generally downward and indicated as to direction and magnitude by vector V_(RO). Also, preferably the filaments are extruded from the biased extrusion orifices at an angle corresponding to the desired netting geometry.

Similarly, FIG. 6 shows a portion of inner die 23 having an extrusion orifice 27 angled with respect to a generatrix of surface 53 at an angle about 45° away from the horizontal plane of the bottom of the dies, the inner die rotating in the opposite direction from outer die 25. The angular horizontal tangential velocity of the inner die is depicted by velocity vector V_(AI). Filament F_(I) extruded from orifice 27 exits in the direction as indicated by a velocity vector V_(EI) and has a generally downward velocity component V_(RI) and a generally horizontal tangential component V_(HI) equal (but opposite in direction) to the horizontal tangential angular velocity V_(AI) of the inner die. As previously mentioned, the inner die counterrotates relative to the outer die at substantially the same angular velocity, and the rate of flow of plastic to the extrusion orifices 27 and 29 is substantially uniform, plastic being extruded from the orifices at substantially the same speed.

As previously mentioned, filaments F_(I) and F_(O) extruded from the inner and outer dies 23 and 25, respectively, meet on a generally cylindrical surface indicated at 31 in FIG. 2. Due to the conical surfaces 53 and 67 of inner and outer dies 23 and 25, respectively, filaments F_(I) extruded from the inner die have a velocity component diverging generally outwardly in downward direction relative to die axis X--X, and the filaments F_(O) extruded from orifices 29 in the outer die have a generally inward component in downward direction converging toward axis X--X. These oppositely directed velocity components of filaments F_(I) and F_(O) are advantageous in forming intersections I. More particularly, when orifices 27 and 29 of the inner and outer dies 23 and 25, respectively, are in register with one another at their lower ends, the still-molten plastic filaments extruded from the orifices of the inner and outer dies are caused to impinge togheter to enhance the formation of an intersection I. Since these converging and diverging directions of the filaments are opposite one another and since the filaments extruded from the orifices have substantially the same extrusion velocity, these converging and diverging velocity components cancel out, thus causing the netting formed thereby to move generally in downward direction as represented by the velocity vector V_(RO) and V_(RI) in FIGS. 5 and 6.

Since the filaments F_(I) and F_(O) move downwardly relative to dies 23 and 25, respectively, at substantially the same speed (as indicated by vectors V_(RI) and V_(RO) in FIGS. 5 and 6), and since the filaments are extruded at substantially the desired netting geometry and thus need not be bent while still molten to conform to the netting geometry, there is substantially no relative shear movement between the filaments upon forming intersections I. Thus, intersections I have substantially greater strength and are better able to withstand subsequent stretching operations without delamination of the filaments at the intersections.

The method of this invention of extruding tubular plastic netting N involves extruding a first generally circular series of filaments F_(O) with each of the filaments of this first series inclined in one direction with respect to a plane (not shown) including the longitudinal axis of the netting (i.e., axis X--X). The method further involves extruding a second generally circular series of filaments F_(O) concentric with the first series with each of these second series of filaments inclined in the opposite direction of the first series of filaments with respect to the above-mentioned plane including the longitudinal axis of the netting. The first and second series are rotated in opposite directions at respective angular velocities such that the resultant horizontal tangential velocity of the filaments upon extrusion relative to a stationary point is approximately zero. Each of the first and second series F_(I) and F_(O), respectively, is rotated in such direction that the filaments trail in respect to the direction of their rotation. More particularly, the filaments F_(I) are extruded on a first conical surface 53 and the second series of filaments F_(O) are extruded on an oppositely angled conical surface 67, the conical surfaces being convergent toward one another (see FIG. 2).

It will be understood that certain features of the invention, e.g., extrusion via inner and outer dies with biased orifices or slots (inner and outer die orifices or slots inclined oppositely to a plane including the longitudinal axis of the dies and the netting) counterrotating at an angular velocity such that the resultant tangential velocity of the filaments relative to a stationary point is approximately zero, may be applicable to production of netting via dies shown in U.S. Pat. No. 2,919,467 wherein the intersections are integrally extruded as distinguished from being formed outside the dies.

In view of the above, it will be seen that the several objects of the invention are achieved and other advantageous results attained.

As various changes could be made in the above constructions and methods without departing from the scope of the invention, it is intended that all matter contained in the above description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense. 

What is claimed is:
 1. The method of extruding tubular plastic netting comprising extruding a first generally circular series of filaments with each of the filaments inclined in one direction with respect to a plane including the longitudinal axis of the netting, extruding a second generally circular series of filaments concentric with the first and each inclined in the opposite direction with respect to said plane including the longitudinal axis of the netting, and rotating the first and second series in opposite directions, said first and second series being rotated in such direction that the filaments trail in respect to their respective direction of rotation, the angular velocity of the filaments of the first series and the rate of extrusion of the first series being so related that the resultant horizontal velocity of the filaments of the first series upon extrusion relative to a stationary point is approximately zero, the angular velocity of the filaments of the second series and the rate of extrusion of the second series being so related that the resultant horizontal velocity of the filaments of the second series upon extrusion relative to a stationary point is approximately zero, the filaments of the first and second series being joined at intersections thereof.
 2. The method of claim 1 wherein the filaments of the first series are extruded on a first conical surface and the filaments of the second series are extruded on an oppositely angled conical surface, said surfaces being convergent toward one another. 